RU9552U1 - INDUCTOR ELECTRIC MACHINE - Google Patents

Abstract

1. Inductive electric machine containing a stator, consisting of a magnetic circuit made in the form of several laminated gear packages, and at least one winding, and a rotor containing magnetic circuits, characterized in that the laminated gear packages are made U-shaped and evenly spaced around the circumference with the formation of teeth in the air gap of the machine, and the winding is made annular. 2. The machine according to claim 1, characterized in that the winding is located in the cavities of the U-shaped charge packages. The machine according to claim 1 or 2, characterized in that the magnetic circuits of the rotor are gear. A machine according to any one of claims 1 to 3, characterized in that the air gap is δ = (1/15 ÷ 1/22) τ, where τ is the gear division. 5. The machine according to claim 1, characterized in that the size of the air gap is made to provide the following relationship: σ≥ σ steel; σ steel ≅ σ steel, where σ is the magnitude of the induction of the air gap; σ steel is the magnitude of the saturation induction of steel; σ steel is the magnitude of the induction steel teeth of the rotor and stator. 6. A machine according to any one of claims 1 to 5, characterized in that it is provided with an excitation winding located in a common spool with said winding. The machine according to claim 1 or 6, characterized in that the windings are made of aluminum. A machine according to any one of claims 1 to 7, characterized in that the magnetic circuit is single-phase. A machine according to any one of claims 1 to 7, characterized in that the magnetic circuit is m-phase, and the U-shaped packets of adjacent phases are mounted with a shift relative to each other by τ / m, and the excitation windings of all phases are connected in series. A machine according to any one of claims 1 to 9, characterized in that the rotor comprises a squirrel cage winding

Description

Inductive Electric Machine

This proposal relates to the field of designs of AC electric machines with separated magnetic circuits.

A device is known for an electric machine with separated phases, consisting of stator arc magnetic cores with teeth in a cylindrical gap, a rotor in the form of two symmetrically arranged hollow glasses entering cylindrical sides into the gap of the stator magnetic cores and having teeth, anchor windings covering each stator magnetic circuit and a single ring winding excitation located between the external and internal stator packets of each magnetic circuit (AS No. 1814159, class A1 M. class N 02 K 19/06, 1993).

The closest analogue of the claimed device is an induction electric machine containing a stator, consisting of a magnetic circuit made in the form of a burnt gear package, and at least one winding, and a rotor containing

magnetic cores. (RU, patent 2027285 C1, CL H O2 K 19/06,

A disadvantage of the known machines is the low use of iron stator and rotor packages.

IPC b: N 02 to 19/06

The technical result provided by the invention,

is the exclusion of zones with zero induction on the outer surface of the stator packets and the inner rotor and increase the efficiency of use of the windings, thereby increasing the specific energy and weight and size indicators of the electric machine.

The technical result is achieved due to two versions of the induction electric machine. The first option is an induction electric machine containing a stator, consisting of a magnetic circuit made in the form of several burnt gear packages, and at least one winding, and a rotor containing magnetic circuits, burnt gear packages are made P-shaped uniformly located around the circle with the formation of teeth in the air gap of the machine, and the winding is made annular in the form of an ordinary winding. The winding is located in the cavities of the U - shaped charge packages.

The magnetic circuits of the rotor are gear.

The air gap is

6 (1/15 -f- 1/22) t where t - gear division

The size of the air gap is made providing the following ratio:

CTg ST Steel °

 yy steel - j steel

Steel - the magnitude of the induction of saturation of steel,

Tired - the magnitude of the induction of steel teeth of the rotor and stator

The machine is equipped with an excitation winding located on a common spool with said winding.

The windings are made of aluminum.

The magnetic circuit can be made single-phase or t-phase, and the U-shaped packets of adjacent phases are mounted with a shift relative to each other, and the excitation windings of all phases are connected in series.

The rotor contains a short-circuited teak squirrel cage with straight rods.

The rotor contains a short-circuited teak squirrel cage, the rods of which are transposed in length into four sections, and a pair of internal turns covers a pair of adjacent teeth of adjacent rotor cores.

The second option is an induction electric machine containing a stator, consisting of a magnetic circuit made in the form of a burnt gear package and at least one winding, and a rotor containing magnetic circuit, in which the magnetic circuit is made of electrical steel in the form of a multi-turn solenoid, the outer surface of which is insulated , each turn contains teeth on the inside, on the outside - yoke, laden in the longitudinal plane, while the magnetic core simultaneously serves as a winding.

5 (1/15 -5- 1/22) t

where t - gear division

The size of the air gap is made providing the following ratio:

 us.

CTS (Tired

 ft.

steel - steel

The rotor contains a squirrel cage winding with straight rods.

The rotor contains a short-circuited squirrel cage type winding, the rods of which are transposed in length into four sections, with a pair of internal turns covering a pair of adjacent teeth of adjacent rotor cores.

The analysis will not catch sources that discredit the novelty of the invention.

When establishing the conformity of the proposal with the condition of an inventive step, an induction electric machine was identified (SU, AS 1815570 A1, class N 02 K 19/06, 1993), in which the stator stacked packages were made U-shaped. However, due to the fact that in the proposed machine P-shaped packages are installed in a different plane and, in conjunction with the annular winding, zones of zero induction on the outer surface of the stator packages and the inner rotor are excluded. Thus, the proposal meets the condition of inventive step. (longitudinal section), figure 2 is a transverse section aa, on

Fig.3 is a General view of the rotor with two transposed stubs, Fig.4 is a General view of the lined package of the stator, Fig.5 is a diagram of the connection of the windings, Fig.b is a second version of the stator of the inductor machine, in Fig.7 the teeth of the stator and rotor , in Fig. 8 the dependence of the limiting magnetizing force F on the angle of rotation of the rotor a, in Fig. 9 is a saturation curve for steel.

As follows from figure 1, the engine comprises a housing 1 with stator magnetic circuits 2 and a rotor 3.

The stator of the motor 2 includes a magnetic circuit from sets of gear packages 4-6. Each stator set consists of several U-shaped axially arranged packets (Fig. 4), forming teeth in the gap. The axes of the teeth of each stator magnetic circuit are axially located, the axes of the teeth of the phase packets are displaced relative to each other by 1/3 of the tooth division.

Each stator package of the magnetic circuit contains an anchor winding 10-12, powered by an alternating current network or a converter, and a field winding 16-18 installed concentrically with it, all the stator field windings are connected in series and are supplied with direct current. The presence of these windings allows the machine to work in generator mode.

The windings can be made of aluminum to reduce the weight and cost of the motor.

The rotor 3 consists of three sets of magnetic circuits 7-9, lined in radial planes, mounted on the sleeve 19 on the shaft of the rotor 20. A short-circuit type winding is laid on the rotor

5

squirrel cage, the rods of which 13 are short-circuited by rings 14 and 15 at the ends of the rotor 3.

The rotor is made lined, round, and has a short-circuited squirrel cage winding with straight axial rods, and the teeth of adjacent packages of each magnetic circuit are shifted by half the tooth division.

The rotor winding rods (each adjacent pair of rods) can be transported along the length of 4 sections (partial turns) so that a pair of inner turns covers a pair of adjacent teeth of adjacent rotor phase magnetic circuits, while the polarity of the connection of the middle stator winding is reversed compared to the extreme ones.

The machine can operate in motor and generator mode. Start and operation of the machine in asynchronous mode is carried out by connecting the windings to the network through closed contacts K1-KZ (figa). To put the machine in synchronous mode, the contacts open, and it works with synchronous speed, like an inductor synchronous without excitation.

To control the speed of the machine, the contacts K1-KZ can be replaced by controlled semiconductor devices, for example, thyristors T1-TZ (Fig. 56), controlled from the control system-SU unit.

In the synchronous motor mode, alternating magnetic fluxes shifted by 120 degrees are induced in each of the phase magnetic circuits. email Variable magnetic fluxes in each phase magnetic circuit induce a variable emf in their pair of transposed turns. with network frequency and amplitude

variable rotation according to the law:

UA Uo sin (ot + 0 °) I sin (a + 0 °) | ;

UB Uo sin (ot + 120 °) I sin (a + 120 °) | ;

Uc Uo sin ((ot + 240 °) I sin (a -i- 240 °) |.

The sum of these EMFs in three pairs of transposed turns represents a single-phase variable EMF and current. The interaction of this current with the magnetic fields of the phase magnetic circuits forms a torque.

The transposition of the rods 13 along the length of the middle phase magnetic circuit requires a change in the phasing of the connection of the winding of the middle phase 11 to the network.

To operate the machine in generator mode, it is driven by a third-party engine, the field windings are powered by direct current.

When the rotor rotates, the magnetic flux in each phase magnetic circuit pulsates due to different magnetic resistance. The variable components of the magnetic flux induce in the anchor windings a variable sinusoidal emf shifted by 120 el. hail, in the windings of phase magnetic circuits at high rates of power quality with virtually no distortion of the harmonic shape of the voltage.

To improve the overall dimensions, as shown by theoretical analysis, the value of the air gap 6 is selected from the condition

1

where t is the tooth division.

The second version of the induction machine is shown in Fig.6. The stator magnetic circuit in this embodiment simultaneously performs the function of a winding.

The magnetic core is made of stamped plates of electrical steel in the form of a multi-turn cylindrical solenoid, each coil of which is isolated from each other, on the inside there are teeth, on. external-back-yoke 21, lined in the longitudinal plane of the terminal turns of the magnetic circuit connected to the network or converter.

Combining the functions of the magnetic circuit and the winding in one device allows you to reduce sections by 30-32%. The stamped plates of the magnetic circuit are butt welded to form a coil.

To improve the torque, as shown by theoretical analysis, it is advisable in the machine during the entire phase of the motor mode to have the maximum possible magnetic flux Ф Фтах OR, more precisely, the highest possible induction in steel at the level of the knee of the saturation curve. To fulfill these requirements, it is necessary and sufficient to fulfill the condition

F bg post. max gives a curve of the dependence of the limiting magnetizing force F on

the angle of rotation a of the rotor (hereinafter the restrictive curve). For example, in Fig. 7, a restrictive curve 1 is given (for the case of straight teeth of the machine in the gap) and inductions in steel Bst 1/7 T. The graph shows that the use of this curve makes it possible to increase the motor current and the magnitude of induction in the gap by 2.2 times in the 0 ° - 30 ° section (zone B) (i.e., up to 3.74 T).

The use of chamfers A on the teeth with a leg size equal to

“0.1 t, allows you to significantly expand the zone of the forced current (magnetizing force F) to 90 ° and the amplitude of the current and induction in the gap to 8.6 times (zone C) (i.e. up to 14.62 T)

The use of a type 1 superconductor layer on the lateral sides of the teeth of the rotor and stator increases the amplitude of the current I

(or Г) up to "154-17-fold magnitude of current or induction in the gap.

nine

Claims (17)

1. An induction electric machine containing a stator, consisting of a magnetic circuit made in the form of several lined gear packages, and at least one winding, and a rotor containing magnetic circuits, characterized in that the lined gear packages are made U-shaped and evenly spaced with the formation of teeth in the air gap of the machine, and the winding is made annular.  2. The machine according to claim 1, characterized in that the winding is located in the cavities of the U-shaped charge packages.  3. The machine according to claim 1 or 2, characterized in that the magnetic circuits of the rotor are gear. 4. Machine according to any one of paragraphs.1 to 3, characterized in that the amount of air gap is
δ = (1/15 ÷ 1/22) τ,
where τ is the tooth division. 5. The machine according to claim 1, characterized in that the size of the air gap is made providing the following ratio:
σ _δ ≥ σ have become ^us. ;
σ steel ≅ σ steel ^us. ,
where σ _δ is the magnitude of the induction of the air gap;
σ have become ^us. - the magnitude of the induction of steel saturation;
σ steel is the magnitude of the induction of the steel teeth of the rotor and stator.  6. Machine according to any one of paragraphs.1 to 5, characterized in that it is equipped with an excitation winding located on a common spool with the specified winding.  7. The machine according to claim 1 or 6, characterized in that the windings are made of aluminum.  8. The machine according to any one of claims 1 to 7, characterized in that the magnetic circuit is single-phase.  9. The machine according to any one of claims 1 to 7, characterized in that the magnetic circuit is m-phase, and the U-shaped packets of adjacent phases are mounted with a shift relative to each other by τ / m, and the excitation windings of all phases are connected in series.  10. Machine according to any one of claims 1 to 9, characterized in that the rotor comprises a short-circuited squirrel cage type winding with straight rods.  11. Machine according to any one of paragraphs.1 to 9, characterized in that the rotor contains a short-circuited squirrel cage type winding, the rods of which are transposed four sections in length, with a pair of internal turns covering a pair of adjacent teeth of adjacent rotor cores.  12. An inductor electric machine containing a stator, consisting of a magnetic circuit made in the form of a lined gear package, and at least one winding, and a rotor containing magnetic circuits, characterized in that the magnetic circuit is made of electrical steel in the form of a multi-turn solenoid, the outer surface of the turns which is insulated, each coil contains teeth on the inside, on the outside - yokes, laden in the longitudinal plane, while the magnetic circuit serves as a winding at the same time.  13. The machine according to p. 12, characterized in that the magnetic circuits of the rotor are gear. 14. The machine according to item 12 or 13, characterized in that the amount of air gap is
δ = (1/15 ÷ 1/22) τ,
where τ is the tooth division. 15. The machine according to item 12 or 13, characterized in that the size of the air gap is made providing the following ratio:
σ _δ ≥ σ have become ^us. ;
σ steel ≅ σ steel ^us. .
16. Machine according to any one of paragraphs.12 to 14, characterized in that the rotor contains a short-circuited squirrel cage winding with straight rods.  17. Machine according to any one of paragraphs. 12 to 14, characterized in that the rotor contains a short-circuited squirrel cage type winding, the rods of which are transposed in length into four sections. 18. The machine according to any one of paragraphs.12 to 17, characterized in that the rotor contains a short-circuited squirrel cage type winding, the rods of which are transported four sections in length, with a pair of internal turns covering a pair of adjacent teeth of adjacent rotor cores.